RU2465404C1 - Bench slope reinforcement method - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: bench slope reinforcement method involves well drilling on upper and lower platforms of bench, laying of rope on slope, anchorage of rope ends in wells and rope tensioning. As each below-lying bench is being mined, rope tension force is controlled, as per the data of which additional reinforcement of above-lying benches is performed.

EFFECT: increasing the rigidity of bench slopes and improving the safety of mining operations.

4 cl, 5 dwg

Description

The invention relates to mining, namely, to ensure the stability of the ledges of the sides of the quarries. In combination with geogrid or geo-coverings, it can also be used to strengthen unstable slopes during the construction of roads and railways in mountainous areas in earthquake-prone areas, as The rope-anchor system is a flexible mount and has the ability to damp vibrations.

A known method of strengthening the slopes of earthworks (AS SU No. 535390, publ. 15.11.1976), including vertical drilling of shallow wells on the upper and lower platforms of the ledge, laying ropes on the slopes, anchoring the ends of the ropes in the wells and the tension of the ropes, and after Anchoring of the ends of the ropes pulls together adjacent ropes.

The disadvantages of the method is to strengthen the ledge without taking into account the location of the potential sliding surface, which can lead to deformation of the ledges even after they are fixed, and there is no control of the load acting on the elements for strengthening the slopes of the ledges.

There is a method of strengthening the slopes of the ledges (AS SU No. 626203, publ. 09/30/1978), including drilling wells on the upper and lower platforms of the ledge, laying ropes on the slopes, anchoring the ends of the ropes in the wells and tensioning ropes, and the wells on the upper and the lower platforms are drilled in a checkerboard pattern and each well is connected by ropes with two adjacent wells of the lower edge.

The disadvantages of the method is to strengthen the ledge without taking into account the location of the potential sliding surface, which can lead to deformation of the ledges even after they are fixed, and there is no control of the load acting on the elements for strengthening the slopes of the ledges.

A known method of strengthening the slopes of the ledges (patent RU No. 2239062, publ. 27.10.2004), adopted as a prototype. The method includes drilling wells on the upper and lower platforms of ledges or sub-steps, laying ropes on slopes, anchoring the ends of the ropes in the wells and tensioning the ropes, the length of the ropes being taken so that the anchor, for example, reinforced concrete intersects the potential sliding surface of the ledge.

The disadvantage of this method is the lack of control of the tension force of the ropes laid on the slopes of the upper ledges, and measures to further strengthen the slopes, which reduces the safety of work on the ledges.

The technical result of the invention is to increase the stability of the slopes of the ledges and increase the safety of mining.

The technical result is achieved by the fact that in the method of strengthening the slopes of the ledges, including drilling wells on the upper and lower platforms of the ledges, laying the rope on the slope, anchoring the ends of the ropes in the wells and the tension of the ropes, as each mining of the lower ledge is worked out, the tension of the ropes is monitored, according to the data of which, if necessary, make additional reinforcement of the upstream ledges.

Upon reaching on any portion ropes tension force greater than the ultimate strength embedment anchors with the anchor for safety factor F _n ≥ [V _a] / k _anchor

where P _n - tension force, kN;

P _a - ultimate strength of the anchors, kN;

k _anchor - safety factor for the anchor;

tighten the anchors securing the ends of this rope with adjacent anchors with cable ties.

When any of the ropes reaches a tensile force exceeding the ultimate strength of the rope, taking into account the safety factor for the rope P _n ≥ [P _k ] / k _rope ,

where R _to - ultimate strength of the rope, kN;

k _rope - safety factor for the rope;

make additional laying of the ropes on the slope of the ledge and their tension between the corresponding anchors.

When any of the ropes reaches a tensile force exceeding at the same time its ultimate strength and ultimate strength of embedment of anchors, taking into account the safety factor for both the rope and anchor, P _n ≥ [P _a ] / k _anchor and P _n ≥ [P _k ] / k _rope , additional slope reinforcement is carried out by laying on the slopes and tensioning additional ropes between adjacent anchors, while additional ropes cross each other, and the anchors securing the ends of this rope are pulled together with neighboring anchors.

Figure 1 shows a section of a reinforced section with a force control device located on the rope; figure 2 is a front view of figure 1 with ties anchors on the ledge; figure 3 is a front view of figure 1 with additional laying of the ropes on the slope of the ledge, figure 4 is a front view of figure 1 with additional laying of the ropes and additional tie rods of the anchors on the ledge, figure 5 is a section of a reinforced downstream ledge.

The determination of the tension forces of the ropes, strengthening the slopes of the upstream ledges before working out the lower ones, is carried out, for example, using the device for measuring the tensile forces in guy wires of the type ITOE-10 (Device for monitoring the efforts in guy wires ITOE-10-200. Operation manual. Manufacturer LLC ELNA- NORTH, 2010).

The method is as follows.

Wells 2 are drilled on the upper platform of the reinforced ledge or sub-step 1, in which the upper ends of the ropes are fixed using reinforced concrete anchors 3. Wells 6 are drilled from the lower platform of the ledge 5 in the slope with an excess for the potential sliding surface 7, and reinforced in them using reinforced concrete anchors 8 the lower ends of the ropes 4, produce the tension of the ropes in a known manner, for example, by a mechanical gripping device such as US B-2000. Then the rock mass of the lower ledge 9 is started to be shipped. As the shipment is made, the tension of the ropes 4 is monitored using device 10 (type ITOE-10).

When reaching to any of the rope 4, the tension force exceeding ultimate strength embedment anchors considering the safety factor for the anchor P _n ≥ [V _a] / k _anchor produce contraction ends anchors 3 and 8, fixing the rope with the neighboring anchor rope screeds 11 (figure 2).

When any of the ropes 4 achieves a tensile force exceeding the ultimate tensile strength of the rope, taking into account the safety factor for the rope P _n ≥ [R _k ] / k _rope , additionally lay the ropes 4 on the slope of the upper ledge between adjacent anchors 3 and 8 with crossing ropes between each other and tension (figure 3).

When a pulling force is reached on any of the ropes at the same time exceeding its ultimate strength and ultimate strength of embedment of anchors, taking into account the safety factor for both the rope and the anchor (P _n ≥ [P _a ] / k _anchor and P _n ≥ [P _k ] / k _rope ), additional reinforcement of the slope is carried out by laying on the slopes and tensioning additional ropes between adjacent anchors, while the additional ropes cross each other, and the anchors securing the ends of this rope are pulled together with neighboring anchors (Fig. 4).

Then, wells 13 are drilled from the lower platform of the ledge 12, into which reinforced concrete anchors 14 are mounted that fix the lower ends of the ropes 4, and the upper ends are fixed with reinforced concrete anchors in the wells 2 on the upper platform of the reinforced lower ledge 5 and the ropes are tensioned, anchoring, you can use anchors, securing the lower ends of the ropes, reinforcing the upstream ledge (figure 5).

If there are more than two ledges for each of them, similar operations are performed.

Example

Accept the following inputs: rock climbing, fissured, 2 ledge 18 m in height, fixing ropes made using concrete anchors to limit the strength of embedment [P _a] = 120 kN, while strengthening of slopes used reinforcing semiprovolochnye ropes with a tensile strength [P _k] from 100 to 200 kN.

On the upper site, drill holes are drilled, wells for loosening charges, wells for reinforced concrete anchors that fix the ends of the ropes. In wells of a cutting gap and wells for loosening charges, explosives are charged and borehole charges are blown up. Reinforced concrete anchors are installed in the wells to secure the upper ends of the ropes. The rock mass of the upper ledge is shipped and transported, for example, by a temporary exit. From the formed lower platform of the upper ledge, wells are drilled to the escarpment of the ledge, reinforced concrete anchors are installed in them to fix the lower ends of the upper ledge ropes, the upper and lower ends of the ropes are fixed on the anchors, for example, they are tensioned using a mechanical gripping device of type US В (PRC) with traction force of 20 kN. Reinforced concrete anchors for securing the lower ends of the ropes of the upper ledge are used to secure the upper ends of the lower ledge.

Then the rock mass of the lower ledge begins to be shipped and, as it is shipped, the tension of the ropes is monitored on the upper platform of the ledge using a portable device of the type ITOE-10, which successively measures the tension on each of the ropes. When reaching to any of the rope tension force exceeding fixing strength concrete anchor considering the safety factor for the anchor P _n ≥ [V _a] / k _anchor produce tie anchor the securing end of the rope with two adjacent anchors, redistributing thereby on them pulling forces acting on him.

When any of the ropes reaches a tensile force exceeding its strength, taking into account the safety factor for the rope P _n ≥ [P _k ] / k _rope , additional laying and tension of the rope between the respective anchors is performed. This work is carried out from the upper platform of the ledge and the bulk of the rock mass of the lower ledge.

When a pulling force is reached on any of the ropes at the same time exceeding its ultimate strength and ultimate strength of embedment of anchors, taking into account the safety factor for both the rope and the anchor (P _n ≥ [P _a ] / k _anchor and P _n ≥ [P _k ] / k _rope ), additional reinforcement of the slope is carried out by laying on the slopes and tensioning additional ropes between adjacent anchors, while the additional ropes cross each other, and the anchors securing the ends of this rope are pulled together with neighboring anchors.

After complete shipment of the rock mass of the lower ledge from its lower platform, wells are drilled into the escarpment of the ledge, into which reinforced concrete anchors are installed that fix the lower ends of the lower ledge ropes and the ropes are tensioned.

Claims (4)

1. The method of strengthening the escarpment of the ledges, including drilling wells on the upper and lower platforms of the escarpment, laying the rope on the escarpment, anchoring the ends of the ropes in the wells, the tension of the ropes, characterized in that, as each downstream escarpment is worked out, the tension of the ropes is monitored, according to which produce additional reinforcement of the upper ledges. 2. A method according to claim 1, characterized in that for achieving in any of rope tension force exceeding ultimate strength embedment anchors with the anchor for safety factor F _n ≥ [V _a] / k _anchor
where P _n - tension force, kN;
P _a - ultimate strength of the anchors, kN;
k _anchor - safety factor for the anchor;
tighten the anchors securing the ends of this rope with adjacent anchors with cable ties. 3. The method according to claim 1, characterized in that when on any of the ropes a tensile force exceeding the ultimate strength of the rope is taken into account, taking into account the safety factor for the rope P _n ≥ [R _k ] / k _rope ,
where R _to - ultimate strength of the rope, kN;
k _rope - safety factor for the rope;
make additional laying of the ropes on the slope of the ledge and their tension between the corresponding anchors. 4. The method according to claim 1, characterized in that when at any of the ropes a tensile force exceeding at the same time its ultimate strength and ultimate strength of embedment of anchors, taking into account the safety factor, both for the rope and anchor R _n ≥ [ P _a ] / k _anchor and P _n ≥ [P _k ] / k _rope , additional slope reinforcement is carried out by laying on the slopes and tensioning additional ropes between adjacent anchors, while additional ropes cross each other, and the anchors securing the ends of this rope pulled together with neighboring en ceramics.

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